US564417A - Clutch mechanism - Google Patents

Description

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(No Model.) L. E. WHITON.

, GLUTGHMEGHANISM.

No. 564,417. Patented July Z1, 1896.

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L. E. WHITON.

CLUTCH MEGHANISM.

Patented July 21, 1896.

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L.l E. WHITON. oLUToH MEGHANISM.

No. 564,417. Patented July 21, 1896.

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l L. RWHITON. CLUTCH MECHANISM.

No. 564,417. l .Patented July 21,1896.

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L. E. WHITON. GLUTGHHMEGHANISM. No. 564,417. Patented July 21,'1896.

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UNiTED STATES i PAT-ENT rricn.

LUCIUS E. lVHlTON, OF NEV LONDON, CONNECTICUT.

CLUTCH MECHANISM.

SPECIFICATION forming part of Letters Patent No. 564,417, dated July 21, v1896. Appiieaiontled october 15,1894. serial No. 525,9'01. (No model.)

To all whom it may concern:

Be it known that I, LCIUs E. VHITON, a citizen of the United States, residing at New London, in the county of New London and State of Connecticut, have invented certain new and useful Improvements in Clutch Mechanism, of which the following is a speciiication.

My invention relates to that class of longitudinally-moving clutches having more than one driving-face, which are used for reversing the direction or changing the velocity of the shaft upon which the clutches are mounted, according as the clutch-faces are engaged with different drivers. y

My invention has for its object to provide means whereby such clutches may be given a step-bystep sliding movement, so that intentionally designed and prolonged periods of rest in the revolution of the shaft upon which the clutch is mounted may be provided, to allow intervals during which the performance of other functions of the machine of which the improved clutch mechanism forms some part may occur. Heretofore it has been usual to control the automatic action in each direction of such sliding clutches by means of springs, which cause the immediate engagement of the sliding clutch with another of its drivers immediately after the said clutch is released from one of said drivers. In these cases it has not been possible to provide more than momentary periods of rest in the revolution of the shaft upon which the clutch is mounted owing to the continuous passage of the clutch from one driver to another. lt is frequently of great importance in the design of special machinery that some driving or feeding shaft shall have a prolonged period of rest in order to permit the performance of some other function of the machine the completion of which shall cause the rengagement of the clutch with one of its drivers. An embodiment of the principles of myimproved clutch mechanism may be found in an automatic gear-cutting machine, as described in my application for patent filed February 2S, 1894, Serial No. 501,864, which is one of many possible uses of this improvement in automatically-acting machines.

In the drawings accompanying and forming ing surfaces for engagement with the respective drivers. Fig. 3 is an end view of the right-hand face of said sliding clutch, showing the rack by which same is moved endwise and the projecting ends of the spring-pressed bolts. Fig. l is an end view of the clutch-face of one of the drivers, by means of which said sliding clutch may be caused to revolve. Fig. 5 is a side view of the said sliding clutch, showing its rack-teeth and the gear-segment in engagement therewith by which said clutch is moved. Fig. 6 is a side view of intermittently-actin g mechanism for moving the rockshaft shown in Fig. l and is taken in a direction parallel to the axis of said rock-shaft, the sectional view of the intermittent clutch mechanism shown being taken on the line :r .r of Fig. 10. Fig. 7 is a similar view of the same intermittently-actin g mechanism, showingit in a different position, the section being taken on the line y y of Fig. lO. Fig. 8 is a similar view of a portion of the said mechanism, showing the rock-shaft arm and its operating devices in another position. Fig. 9 is a view of the left-hand end of the intermittent clutcli mechanism shown in Fig.- l0. Fig.

l0 is a side view of the intermittent clutch mechanismv shown in section in Figs. 6 and 7. Fig. l1 is a plan view of a modified form of the clutch mechanism, showing primary and secondary cam movement-s, releasing devices whereby said cam movements may be operated, and a clutch slider or guide in place of the rock-shaft, gear-segment', and rack of Figs: l and 5. Fig. 12 is a view of the right-hand end of the mechanism illustrated in Fig. ll. Fig. 13 is a partial longitudinal section on line y y of Fig. ll, showing the sliding clutch IOO and the drivers by which same is operated and spring-pressed bolts mounted within one of the driving-clutch hubs to afford yielding engagement with the sliding clutch. Fig. 14I is an end View of the said clutch-hub, showing the projecting ends of the sliding bolts referred to. Fig. 15 is an end view of one of the faces of the sliding clutch,showing notches engaged by the projecting bolts of Figs. 13 and 14. Fig. 16 is a plan view 'of a portion of the primary-cam mechanism illustrated in Fig. l1, showing this cam mechanism and its releasing device in a different position. Fig. 17 is a sectional view, taken on line fr .r of Fig. 11, showing the method of mounting certain releasing devices which allow the secon dary cam to operate. Fig. 18 is a cross-section on lines z ,e of Fig. 16, showing the intermittently-acting mechanism by which the primary clutch-sliding cam is operated. Fig. 19 is a detached view of the secondary cam shown in Fig. 11, by means of which the sliding clutch is given a portion of its movement in one direction. Fig. 2O is a view showing the application of gearing by which the time required for the revolution of the secondary cam shown in Fig. 19 may be varied. Fig. 21 is a plan view of a modified form of the mechanism shown in Fig. 11, in which the pri ma ry-cam mechanism for sliding the clutch in one direction is omitted. Fig. 22 is a side view of the mechanism shown in Fig. 21, and also illustrates the application of springs to slide the clutch in one direction in place of the omitted primary-cam mechanism of Fig. 11. Fig. 23 is a face view of the left-hand driving-clutch of Fig. 2l, showing pawls by which the sliding clutch is revolved. Fig. 2 is a view of that end of the sliding clutch which engages the face of the driving-clutch shown in Fig. 23.

The working parts illustrated may be mounted inV proper working relation in any suitable position upon the framework of the machine in which the improved clutch mechanism is to be utilized. I have deemed it unnecessary to show forms of framing, as such forms may be designed to suit the circumstances by those skilled in the art to which the invention appertains.

In explaining this invention in detail, the simplest form will be first described, as shown in Figs. 2l, 22, 23, and 21 of Sheet 5, Figs. 12, 19, and 2O of Sheet 4, and Fig. 17 of Sheet 3.

Referring to Fig. 21, 30 represents the shaft, upon which the clutch 31 is fitted to slide, being prevented from turning independently of the shaft by the spline or feather 301, as shown in Fig. 24, or otherwise. The clutch member 31 is provided at one end with radial clutchteeth 31A and at the other end with ratchet- ,teeth 3l, (see Fig. 24,) and is also provided with an annular groove 31C.

raised hub 32A. These pawls tend to keep in contact with said hub by the action of springs 32C. This revolving driver is shown as a wormgear, and it is intended to convey only a slow4 motion to the shaft 30 when clutch member 31 is engaged therewith; but it may be caused to revolve in any other convenient manner. 33 is also a revolving driver mounted to turn freely upon shaft 30, and is provided with projecting radial clutch-teeth 33^. 34: is a slider which may be mounted upon any suitably-designed portion of the framework, and is provided with a projecting yoke 345A, which engages the annular groove 31C of the clutch member 3l. A spring 342B tends normally to move the slider toward the right hand, (see Fig. 22,) but the said slider is restrained by the latch 35, kept normally seated in the recess 310 by the spring 35A. A stop-rod 35B is attached to the latch 35, which may be operated by hand or by some portion of the machine of which the clutch mechanism forms part. Then the slider 34 is restrain ed in the left-hand position by the latch 35, clutchteeth 31B are in engagement with and driven by the pawls 32B of the driver Vhen' the slider is in the right-hand position after the release of the latch 35, clutch-teeth 3lA are in engagement with the teeth 33A of the driver 33, and the clutch member 3l and shaft 30 will be revolved by the driver 34 is a stop-rod attached to the slider 34E.` The slider 34 is also provided with rack 34E (see Fig. 21) and meshes with segmental gear 36, forming part of a releasing mechanism, and pivoted upon stud 36, attached to some suitable portion of the framework. (See Figs. 12 and 21.7.) Pinion 36 is provided with projecting hub 36B, having mounted upon its upper end the ratchet 36C. The circular disk 36D, provided with notches 36E, is also mounted independently of the pinion 36 and hub 36, but concentric therewith,` and in a manner permittingit to revolve in only one direction. I have not shown details of this mounting, as various forms of mountin gs which will accomplish the specied result will readily occur to those skilled in the art. The said disk 36D is provided with pawl 36F and spring 36, tending to keep said pawl in engagement with the ratchet 36C. 37 is a constantly-revolving shaft suitably mounted in some portion of the framework, and provided with clutch-disk 37A of interior construction similar to that shown in Fig. 6, Sheet 2, being provided with the inwardly-projecting driving-lugs 39B there shown. 3S is an intermittentlyrevolving shaft independent of the shaft 37, and provided with cluteh-disk 38A and cam 38B. The clutch-disk 38A is constructed as shown in Figs. 6 and 9 of Sheet 2, being provided with a pawl like the one there shown as 40E, having the projection LOG and the spring 40" tending t-o rotate the said pawl whenever possible, so that it may be engaged by the driving-lu g 39B. This pawl 40E, with projection 40G of Fig. 6, is shown and referred to as 38C in Fig. 2l.

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The operation of the described mechanism is as follows: Assuming clutch member 31 to be in engagement with its driver 32, a movement of the latch 35, either by hand or by the stop-rod 35B, compresses spring 35A and releases slider 34, which is forced to the right by the spring 34B untilthe clutch-teeth 31A are in engagement with the teeth 33A of the driver 33 and the direction or velocity of shaft is changed, as the case may be. This movement of the slider 34 revolves the pinion 36 slightly, and also the ratchet 36C, and as the notched disk 36D is so mounted that it cannot revolve in this direction the engagement of the pawl 36F with the next adjoining ratchet-tooth occurs. The clutch-teeth 31A and 33A are made of proper depth, so that before same can become disengaged by the lefthand movement of the slider 34 the 'said slider will have traveled approximately onehalf of its possible stroke. 1f the slider 34 be moved to the left by the application of sufficient force to the stop-rod 34D until the clutch-teeth 31A and 33A are disengaged, (forming the first step in the return sliding movement of the clutch member 31,) the pinion 36 will be partially revolved in a direction opposite to its iirst movement. This movement will also revolve the ratchet 36C, and on account of the contact of pawl 36F it will move the notched disk 36D a sufficient distance to release the pawl 38C of the clutch member 38A, permitting it to engage with the constantly-revolving driver 37A and. to revolve through the notch 36E, causing revolution of the shaft 38. During this revolution of shaft 3S the shaft 30 will remain at rest, since the clutch member 31 will occupy the neutral position, out of engagement with both the driver 33 and the driver 32. The described revolution of shaft 33 will also revolve the cam 38B, mounted thereon, which will come in contact with the arm 36H, suitably attached to the segmental gear 36. Continued revolution of the cam 38B will push the arm 36H aside, revolving the segmental gear 36 partially in the same direction in -which it was started by the described lefthand movement or first return step of the slider 34. The segmental gear 36 thus becomes the driver, and by means of the rack 34E the slider 34 will be moved another step to the left, compressing the spring 34B, allowing the latch 35 to snap into the depression 34C, and causing the engagement of the clutch-teeth 31B and pawls 32B of driver -32. This partial revolution of pinion 36 will have also partially revolved the stop-disk 36D, so that the tooth 36J will be in the path of the revolving clutch-pawl 38C, mounted in the clutch-disk 33A. Upon contact of this pawl with the obstacle thus placed in its path of revolution it will become disengaged from its driver 37A and shaft 33A will come to rest.

It will be seen that the mechanism thus described gives the clutch 31 a continuous spring-pressed sliding movement in the righthand direction equivalent to its full stroke and a step-by-step sliding movement in the opposite direction, allowing the shaft 30 a period of rest, during which shaft 37 is revolving, and that the said shaft 38 may be utilized as a source of power for the performance of any other function of the machine during its revolution, while the shaft 30 is remaining at rest; also, that the completion of the revolution of the cam 38B will cause the nal return of the clutch and slider to the iirst position.

While the described form of the mechanism shows segmental gear 36 and its attached releasing devices in immediate connection with the slider' 34, yet 1 do not wish to limit myself to this construction,as it will be readily seen that any necessary connecting elements maybe introduced between the sliding-clutch member 31 and the segmental gear 36, if it is found more convenient to locate the releasing mechanism at some distance from the clutch,

such constructions being within the scope of myimprovement. It is unnecessary that the shafts 37 and 38 be independent shafts, as the clutch-driver 37'A may be a separate piece loosely mounted upon a prolongation of the shaft 38, if desired. It is also unnecessary that the cam 33B be attached directly to the revolving shaft 38, as it may frequently be desirable to allow the shaft 30a longer period of rest than would be allowed by a single revolution of the shaft 38. Thus, by mounting the cam .38B upon a separate shaft 38D, (see Figs. 19 and 20,) which may be connected by suitable gearing .with shaft 38, its velocity may be greatly varied from that of the shaft 38, allowing more or less time for the revolution of the said shaft 38, and consequently a longer or shorter period of rest for the shaft 30, as may be required.

Since the iinal return step in the movement of the clutch-slider 34 may occur while, the constantly-revolving driver 32 is in any position, it is not advisable to provide they said driver and the sliding clutch with positivelyengaging teeth similar to the teeth 31".` and 33, since the movement of the slider 34 might occur at such a time that the raised portions of the clutch-teeth would abut against each other, preventing proper action of the mechanism and causing damage. It is therefore necessary that these clutch-surfaces should be yielding surfaces so designed as to afford no obstacle to the return of the clutch into engagement therewith in any position of the driver 32. The several drawings illustrating the clutch mechanism show a variety of forms of such yielding surfaces, any yielding surface accomplising the desired result being an equivalent element of the invention.

The spring-pressed pawls 32B, attached to the face of the driver 32, as shown in Fig. 23, in combination with the ratchet-teeth 31B of the clutch member 31, as shown in Fig. 24, constitute one form of such yielding action, it being understood that the end of the slidingclutch member 3l is beveled off slightly, as

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indicated at 31D, so that in case the advancing ratchet-teeth are not in proper position to be engaged by the pawls 32B the said pawls will be raised slightly bythe tapered portion of the sliding-clutch member 31, and will seat themselves in contact with the ratchet-teeth of the sliding-clutch member when the driver has revolved sufficiently.

A second form of such yielding clutch-surfaces arranged to operate at each extremity of the sliding motion of clutch member 31 is illustrated in Fig. 13, in which both the clutch driving-hubs are recessed to receive springpressed bolts which will be forced back into the body of the clutch-driver in case the advancing sliding clutch does not register properly with the projecting driving-surfaces, the said driving-surfaces being forced out into proper engagement whenin suitable relation.

A third form of the necessary yielding surfaces is shown in Fig. 2, in which the clutchbody is provided with oppositely-disposed spring-pressed bolts adapted to yield to end pressure and be forced out into proper engagement with the respective drivers when in a position to register therewith.

Any form of yielding clutch-surface which is most conveniently adapted to other circumstances iniiuencing the proper design of the clutch mechanism is within the scope of my invention, as will be readily understood.

As a result of the use of the spring 34B for :forcing the slider 3l to the right, giving it its first movement, there will of necessitybe considerable shock to the mechanism when the clutch member 3l abuts against its driver 33, tending to cause undue wear and damage. The action of the spring may also prove somewhat unreliable. It is therefore desirable to substitute some mechanical means for moving the said slider 3l and the connected clutch to the right, which shall avoid this un certainty of action, shock, and ccnsequentstrain and wear. Aform of such a substitute mechanism and some of its details are shown in Figs. 11, 12, 16, and 1S, in which cams are used to give the necessary travel to the slider 3l. To distinguish these cam movements from the cani movements already described, they are termed the primary cam movements. Those already described will hereinafter be termed the secondary cam movements. The shaft 30, sliding-clutch member 31, drivers 32 and 33, slider 34, the secondary-cam mechanism, and the releasing devices which allow the same to operate are constructed in the same manner as heretofore described, except that the teeth 31A of the said clutch do not project as much as in the previouslydescribed form. The primary-cam mechanism referred to is constructed as follows: A constantly-revolving shaft 39 is mounted in some suitably-designed portion of the framework adjacent to the slider 34, and is provided with a constantlyrevolving clutch-disk 39A. A second and independent shaft i0 is mounted in such a manner as to be in axial alinement with the shaft 39, and is provided with clutch-disk 402 releasing-rin g 40B, having stop-lu gs 40C and 40, and containing the pawl 40E, as shown in Fig. 18. The releasing-ring 40B is provided with an internal notch 1101", which engages the projecting end 40G of the pawl 40E. A spring 40H tends constantly to move the stop-ring 40B slightly in a manner which will cause the engagement of the pawl L10E with projections 30B of the constantly-revolving driver. The shaft L.L0 is also provided with a cam 51.0, having the irregularly-shaped cam-groove 40N, adapted to move the slider 34E when revolved. The yoke 34A of slider 3l is extended, forining projection Bill, and carries a roller 34:, (see Fig. 12,) which projects within the eamgroove 40X, heretofore described. A stop-rod 4:1 (see Fig. 1l) is suitably mounted in the framework, and is provided with stop-collar atlA and notched releasing-stop 41B, and passes through a recess in the proj ectiou 3l-I of slider Si.

The operation of the described mechanism is as follows: Assuming the slider Sel and clutch member 3l to be in the left-hand position with the clutch in engagement with its driver 32, pressure upon the stop-rod l1 will act first upon `the projection .l/-LF of the slider 3i because of the contact of stop-collar 4l* with the said projection 3F" and will move the said slider 34 slightly to the right, it being understood that the contour of the eamgroove LON where it engages the roller Si is so shaped as to permit the said movement of slider 34. Continued movement of the stoprod 41 will cause the clutch member 3l to become disengaged from its driver 32 and will stop the revolution of shaft 30. This movenent toward the right of the stop-rod 41 will have also moved the notched releasing-stop 4:11, attached thereto, to the right until the notch 41C in the said releasing-stop permits the passage of the projecting releasing-lug 40C. So soon as the stop-ring 40 is thus released it will revolve slightly by the action of the spring 40H, (see Fig. 18,) and the paw] 40E will become engaged with the projection 30B of the constantly-revolving driver 35), and the shaft 4:0, with its attached cam lO-1, will revolve until the second stop-lug 40D of the stop-ring 40B comes in contact with shoulder 41D, which has been advanced toward the right into the path of the revolution of the said stop-lug 40D by the movement of rod il. The obstacle thus placed in the path of the revolution of the said stop-lug 40D will retard the ring 4:0, disengaging the pawl 40E from its driver and allowing the revolution of the shaft 40 to cease. The contour of the camgroove 40N is such that this partial revolution of the cam 40 will move the slider 34- its full stroke toward the right, causing the engagement of clutch-teeth 3lA with the teeth of the driver rlhe projection Sail" of the slider will have then also moved to the right a suiiicient distance to abut against the releasingstop 41B, (see Fig. 16,) and shaft 30 will be rcvolved in the opposite direction, or at a different velocity, as the case may be. If sufficient pressure be now applied to the stop-rod 41 in the opposite direction or toward the left, the slider 34 will be first moved with the said stop-rod slightly to the left until the clutchteeth 3lA are disengaged from its driver 33, stopping the revolution of shaft 30. The primary-cam mechanism will also be again released by the notched releasing-stop 41B, and the cam 40M will make a second partial revolution until stopped by the contact of the lug 40C with the shoulder 41E, as before eX- plained. The contour of this portion of the cam-groove 40N is so made that this second partial revolution of the said cam will withdraw the slider only a portion of the total amount of its travel (forming the first return step in the movement of the clutch 3l) and the slider will remain in the middle position when the primary-cam mechanism comes to rest the second time, allowing vthe shaft to remain at rest. The secondary-cam mechanism will be released by the return of the slider to the middle position, as described in the first form of the mechanism', allowing the performance of some other function by the revolution of the shaft 38 while shaft 30 remains at rest, as before described, andthe said slider 34 will be finally returned to the left-hand position, as shown in Fig. 11, by the completion of the action of the secondarycam mechanism. The sliding-clutch member 3l will thus bemechanically controlled, having a continuous sliding motion in one direction, vcaused by the action of the primary-cam mechanism, and a step-by-step sliding motion in an` opposite direction, caused by the described action of boththe primary and the secondary-cam mechanisms.

It will be seen that the primary-cam mechanism may be located at any convenient distance from the slider 34 by the interposition of necessary connecting-links, if the design of the machine renders this removal of the mechanism convenient, Wit-hin the scope of the invention. It will also be seen that the cam M may be mounted on a separateshaft connected by gearing with the intermittentlyacting clutch 40A, if desired. Other variations in the .constructive details of the primary-cam mechanism are possible within the scope of my invention, the arrangement described being a compact form and including only the necessary elements for its proper action.

A further modification of the improved clutch mechanism is shown in Figs. 1, 2, 3, 4, 5, 6, 7, 8, 9, and 10, in whicha rock-shaft, connected to the sliding clutch by means of a gear-segment and rack-teeth and intermittently-acting mechanism for rocking the said shaft to give the clutch its proper sliding movements, are. substituted for the guidingslider 24, yoke 34A, andprimary-cam mechanism of the form previously described. 1 This latter form is the special form of clutch mechvwith the rack-teeth 31H.

anism embodied in the improved gear-cutting machine described in my application for patent, filed February 28,1894,Serial No. 501,864. In this modified form of the mechanism the clutch-body 31 is provided with recesses, in

which oppositely disposed spring pressed bolts 31E are fitted, and retained in place by bands 311". The clutch-body 31 is also surrounded by a band 313', provided with rackteeth 31H and projection 315, by which said band is prevented from revolving with the clutch-body. 42 is a rock-shaft suitably mounted in the framework of the machine, provided with gear-segment 42A,which meshes (See Fig. 5.) Referring to Figs. 6 and 7, 39C represents a constantly-revolving shaft, suitably journaled in the framework parallel to the rock-shaft 42, and corresponding in function to the shaft 39 of the primary-cam mechanism of Figs. 11 and 16, previously described. Attached to the said shaft 39C is a clutch-driver 39D, provided with internal lugs 39B. Loosely mounted upon said shaft 39C, adjacent to the clutch-driver 39D, is an intermittently-revolving element 40K, provided with pawl 40E, having projection 40G and spring 40H. also provided with gear-teeth 40s and annular groove 40T. (See Fig. 10.) Referring to Fig. 6, the rock-shaft 42 is provided with a rigidlyattached arm 42B, having extensions 42C and 42D and the relatively wide opening 42E. lt has also projection 42", in which is mounted roller 42". Suitably j ournaled within the framework adjacent to the arm 42B is an intermittently-revolving element 43, having gear-teeth 43A,which mesh with the gear-teeth 40S ofthe element 40K, as shown in Figs. 6 and 7. The -said revolving element 43 is also provided with an eccentrically-mounted stud or roller 43B, which projects within the opening '42E of the arm 42B. Suitably pivoted upon the stud 44A in the framework at a proper distance from Vshaft 39C is an escapement-lever 44, to which stop-rod 44B is attached. escapement-lever 44 is provided with escapement-points 44C and 44D, which are adapted to engage and release the projecting portion 40G of the pawl 40E. The escapement-lever 44 is also provided with an extension 44E, adapted to engage with the projections 42C and 42D of the'element 42B. Suitably mounted within the framework at right angles to the rock-shaft 42, but not intersecting same, is an intermittently-revolving shaft 38D, provided with cam 38B, the said shaft 38D and cam 3SB being an equivalent of thesecondarycam mechanism heretofore described.

, The operation of this third form of the improved clutchmechanism is as follows: It being assumed that the clutch 31 is in the lefthand position in engagement with its driver 32, the mechanism for moving the rock-shaft will be in the position shown in Fig. 6. lf sufficient pressure be now applied to the stop- `rod 44B in a direction to move it toward the left, the escapement-lever 44 will be revolved Said element 40R is IOO IIO

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slightly about its pivot 44A, and the projection 44E being in contact with projection 42D of the rock-shaft element 42B the rock-shaft 42 will also be partially revolved, causing the sliding clutch 3l to move slightly toward the right and withdrawing its teeth from those of its driver 32. The described movement of the escapement-lever 44 will have also moved the escapement-lever projection 44D to the right to a sufiicient distance to free the projecting end 40G' of the pawl 40E, when the spring 40H will have moved the said pawl, causing it to engage the projection 39B of the constantly revolving driver 39D. The element 40R will then make a partial revolution until its motion is arrested by the contact of the pawl 40G with the escapement-point 44C, which will have also been moved to the right into the path of the said pawl. Through the action of the gear-teeth 40s and 43 the element 43 and its projecting eccentric-roller 43B will have also been revolved partially, and the contact of the said roller 43u with the wall of the openin g 42E will have given the rock-shaft 42 a further rocking movement, causing the sliding clutch 3l to move farther to the right until its teeth have become engaged with the teeth of the driver 33, changing the velocitjT 0r reversing the direction of the shaft 30, as the case may be. If sufficient pressure be new applied to the stop-rod 44B in the opposite direction, or toward the right, the described action will be reversed. The contact of the extension 44E of the escapement-lever 44 with the projection 42C of the rock-shaft element 42B will rock same slightly in the opposite direction, or toward the left, withdrawing the teeth of the sliding clutch from contact with those of the driver 33 and permitting the shaft 30 to stop revolving. The described movement of the escapement-lever 44 will also swing the escapement-point 44C out of the path of the projecting pawl, permitting it to engage with its constantly-revolving driver, and revolve partially until again stopped by its contact with the projection 44D,which will have been swung into its path of revolution. This partial revolution will cause the revolving element 43 to make a corresponding partial revolution, and the contact of the eccentric-roller 43B with the opposite wall of the opening 42E in the rockshaft arm 42B will move same still farther to the left; but on account of the relatively wide opening 42E in the rock-shaft arm 42B the said rock-shaft 42 will be caused to revolve only aportion (approximately One-half) of the an gular movement necessary to return the slidingclutch 1n echanism 3l to its extreme left-hand position in engagement with its driver 32. This partial revolution of the rock-shaft 42 will also serve to release the secondary-cam mechanism, setting in motion shaft 38D and cam 38B, Contact of the said cam 38B with the roller 42G of the rock-shaft element 42 will move the rock-'shaft 42 a farther distance, causing the sliding-clutch mechanism 31 to move to its extreme left-hand position in engagement with its driver 32 and starting the revolution ot the shaft 30, the working parts returning to the position shown in Fig. G. In this form of the improved clutch mechanism the rock-shaft 42, besides serving to move the clutch mechanism 3l, also corresponds in function with the element 3GB of the secondary-cam mechanism, as shown in Fig. 17, the construction of the secondaryeam-mechanism-releasing devices being varied in details sufficiently to permit this com bination of effects, as shown in complete detail in the drawings forming part oi' the patent application already referred to.

It may be mentioned that a further advantage exists in sliding the clutch mechanism 3l mechanically from one to the other ot' its drivers. The described movements of the stop-rods 41 ot' Figs. l1 and 16 and 44B oi' Figs. 6 and 7 serve, first, in each case to release the engagement of the teeth ot the sliding clutch with the respective drivers and aitord means for positively determining the time when the shaft 30 shall cease to revolve. In that form of the mechanism first described, in which the slider 34 is moved in one direction bythe action of the spring 34B, the movement of the stop-rod serves only to release the retaining-latch and does not positively determine the time when the revolving shaft 30 shall stop, since this depends entirely upon the prompt or sluggish action of the spring 34B.

I do not wish to limit myself to the use oi the speciiically-described forms of intermittent clutches in operating'I the primary and secondary cam mechanisms, since it is obvious that any other forms oi' intermittentlyacting clutches by which the several elements may be given partial or complete revolutions as required will be equivalent devices,

It is not essential that the sliding clutch 3l be mounted between the drivers 32 and 33, as shown, since equivalent effects may be produced by the use of a series of clutches and drivers and alterations in the construction of the clutch-slider 34, whereby the same.

may be made to meet the changed conditions.

It is also possible within the scope of my invention to provide a series of steps in the movement of the said clutch-slider in each direction, if demanded by any peculiar funetion of the shaft upon which the clutch mechanism is mounted, as such a series of step movements may be accomplished by a corresponding series of cam mechanisms similar to the secondary-cam mechanism herein described.

I-Iaving thus described my improvement and some equivalent variations in the details of its application, I claim as new and desire to secure by Letters Patent-q l. In combination, a shaft, clutch-drivers loosely mounted thereon, a slidable clutch member splined on said shaft and adapted IOO IIO

to engage said drivers, clutch operating mechanism consisting of primary meansfor moving the slidable clutch member from engagement With one driver into engagement with the opposite driver, secondary means for returning the slidable clutch member to its neutral position, tertiary means substantially as described for returning said slidable clutch member to its initial position, and mechanism intermediate said secondary and tertiary means forv setting inA operation the latter, substantially as set forth.

2. In clutch mechanism, the combination with a shaft, of revolving drivers loosely mounted upon the said shaft and provided With clutch-surfaces, a sliding-clutch mechanism mounted upon the said shaft and adapted to engage With the said drivers, a slider or guide engaging the said sliding-clutch mechanism, a pinion for moving the slider, an in- .termittingly-movable notched disk connected with the pinion, whereby the pinion is adapted to move the said slider or guide in a series of step-by-step movements, and releasing devices for setting the said disk and pinion in action, substantially as described.

3. In combination, clutch-sliding mechanism consisting of a spring-actuated slider 34 tending to move always in one direction, primary means, as stop-rod 34B, for first moving the said slider ashorter distance in the Opposite direction, secondary means, as releasing'- disk 36, intermittently-acting cam 38B, and

mechanism conncCtllg the said cam and the said slider for continuing the shorter movement of the said slider, and means, as latch 35, for retaining and releasing the said slider, substantially as described.

4. In combination, clutch-sliding mechanism consisting of a slider 34, means, as stoprod 4l and attached stop- collars 41A 41B for moving the said slider partially in either direction, and means, as intermittently-acting cam 40M for continuing the movement of the said slider in either direction, so organized as to move the said slider farther in one direction than in the opposite direction, substantially as described.

5. In combination, clutch-sliding mechanism consisting of slider 34, means, as stoprod 4l and attached stop- collars 41A 41B for moving the said slider partially in either direction, means, as intermittently-acting cam 40M for continuing the movement of the said slider in either direction, so organized as to move the said slider farther in one direction than in the opposite direction, and means, as

releasing-disk 36, intermittently-acting cam l

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